Constructs with BBa_J61100 (RBS 1) showed minimal fold-change in fluorescence levels (0.73 +/- 0.316). The second RBS from the Anderson library (BBa_J61101, RBS 2) had a distinct increase in fold change compared to BBa_J61100 (18.15 +/- 3.21 compared to 0.73). The synthetic RBS (RBS 3) designed by the Salis-lab calculator (calculated for maximal expression strength for mKate2 mRNA) showed the strongest fluorescence (48.56 +/- 3.394).
Although RBS 3 showed highest expression strength, RBS 2 was used for the final operon as the binding was independent from the coding sequence (CDS).

4.3.2 sRNA comparison

Before ordering the different sRNA constructs, in silico analysis of the free binding energy of sRNA-mRNA hybridization was calculated and compared to literature to ensure efficient repression (figure 9).

The 27 different sRNA constructs were tested using three different scaffolds, previously used for synthetic sRNA repression, and three different binding sites. The scaffolds SgrS and MicC were chosen since they have been used by previous iGEM teams (e.g. Team Peking 2011, Team Edinburgh 2018, Team UT-Tokyo 2013) and have been established in the literature (No et al., 2019). As they lack characterization in bacteria other than E. coli , we could establish sRNAs in the novel chassis P. fluorescens . Additionally, an engineered version of SgrS (SgrS-S CUUU 6 nts stem (SgrSmt)), optimized for repression in E. coli DH5 alpha, was chosen (Noh et al., 2019). Seed regions (homologous to the mRNA) were chosen with 25 bp homology, targeting either the RBS (target 1), both the RBS (12 nt) and CDS (13 nt) (target 2), or the CDS starting with AUG (target 3).

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All constructs were tested with endpoint measurements in early stationary phase to see the maximum repression capability (figure 8). Seed regions with target 3 showed the weakest repression rates (0.367 +/- 0.118 mean repression compared to 0.544 +/- 0.153 and 0.569 +/- 0.102, for target 1 and 2 respectively). Seed regions with target 1 showed the strongest repression regardless of the RBS used.

The final operon construct contained the seed region targeting only the RBS (target 1, RBS2: BBa_J61101) with the SgrS and MicC scaffolds, as they showed the highest repression strength and the RBS was not designed for a specific mRNA sequence.

4.3.3 comparison of experimental data with previously calculated properties

After conducting repression experiments with all sRNA constructs, possible correlation between the relative repression strength and calculated free binding energy was calculated.
Figure 9 shows repression strength against the free binding energy. For all three tested targets no correlation between binding energy could be found. Interestingly target 3 showed an overall increased variance (0.0678 mean error) compared to target 1 (0.042 mean error) and target 2 (0.0422 mean error).

4.4 Final operon assembly

The XylS-K38R-L224Q on the pSEVA438 plasmid was used as a basis for assembling the final operon. The vector was linearized by PCR, adding homologous overhangs for pAlkB and AlkS sequences. A new sequence containing RBS 2 (BBa_J61101), BsaI restriction sites, and the LUZ7T50 terminator (Ba_K4757058), was synthesized with homologous sequences (IDT). All three insert fragments (pAlkB, RBS2-BsaI-LUZ7 T50) were assembled using Gibson assembly.
Golden Gate assembly, with BsaI restriction enzyme, was used for inserting mKate2 behind RBS 2 (figure 10). Insert and vector sequences were verified with sequencing, but after multiple attempts with different molar ratios, they could neither be successfully combined nor transformed into either P. fluorescens or E. coli DH5 alpha.

 

5. Results

5.1 PE-degradation Sensor (AlkS-V760E/pAlkB)

The final PE biosensor has the AlkS-V760E transcription factor constitutively expressed by the pEM7 promoter and the AlkS-V760E/pAlkB expression strength is measured with mKate2 fluorescence as a reporter gene.

Different n-alkanes emulsified in Tween® 80 (0.1 % (v/v)) were tested as inducers of mKate 2 at different concentrations (100 mg/L, 200 mg/L) with time-resolved fluorescence measurements (figure 11). Only n-dodecane showed a change in fluorescence intensity and was used for further testing of the induction of AlkS at different concentrations.

Serial dilution experiments of n-dodecane emulsified in Tween® 80 were performed and fluorescence intensity measured over 20 h (figure 11). Expression strength was calculated 6 h, 12 h and 20 h after induction with different concentrations, ranging from 2 mg/L up to 2000 mg/L. Twelve hours after induction, significant increases could be measured with inducer concentrations smaller than 200 mg/L (p<0.01). At 20 h concentrations as low as 20 mg/L were sufficient to measure a significant change in fluorescence (p<0.01). The fluorescence measurements at 20 h were used to further analyze the dose-response curve (figure 12, left), showing inducer saturation above 2000 mg/L n-dodecane.

5.2. PET-degradation sensor (XylS-K38R-L224Q/Pm)

XylS-mt was first tested with the native Ps1/Ps2 promoter system, with different inducer compositions of TPA and 3-methyl-benzoate (MBA). The Ps1/Ps2 promoter was substituted with the constitutive promoter pEM7 using add-on PCR. TPA and MBA were tested separately in serial dilutions experiments (figure 13), and in combination (figure 14).

5.2.1. Ps1/Ps2 XylS-mt (with MBA or TPA)

Serial dilution experiments of only TPA showed significantly increased fluorescence compared to the uninduced controls for concentrations above 1 mM at 8 h and 12 h after induction (p<0.01) (figure 13, C). The same experiments performed with MBA as an inducer showed an overall stronger expression strength and significant changes in fluorescence after induction with 0.01 mM MBA (p<0.001) (figure 13, A). The calculated dose response curve (figure 13, (B)) shows inductor saturation at 0.1 mM. For induction of TPA, no inductor saturation was observed (Figure 13, D). The fluorescence intensity of the XylS-WT compared to the XylS-mt shows an overall decreased expression strength. (figure 13, E)

5.2.2. Ps1/Ps2 XylS-MT TPA and MBA co-induction

To further test the influence of the Ps1/Ps2 promoter system on XylS-mt, the co-induction was tested with previously determined MBA and TPA concentrations. Three TPA concentrations were tested with one of four MBA concentrations. Fold change and normalized fluorescence were calculated (figure 14, left). At an MBA concentration of 0.0025 mM, a significant TPA dependent fold change could be measured (1.29 +/- 0.056, p < 0.001). Higher MBA concentrations (0.0075 mM MBA, 0.015 mM MBA) showed an overall decreased fold change. Decrease after TPA induction is due to referencing errors caused by TPA precipitation. The expression strength shows an overall decreased fluorescence intensity at low MBA concentrations, despite co-induction with TPA (figure 14, right)

5.2.3. pEM7 XylS-MT

Alternative to the Ps1/Ps2 promoter system, the constitutively active pEM7 promoter was tested, which was previously used for the expression of AlkSV760E. The new promoter showed overall higher fluorescence intensities, compared to the previously tested Ps1/Ps2 promoter system. Significant changes above induction could be measured with 0.005 mM MBA (p<0.001) or 1 mM TPA (p<0.05) (figure 15).

5.3. sRNA mediated repression

5.3.1. SgrS1.2/MicC1.2 repression

The scaffolds SgrS and MicC with the RBS 2 (BBa_J61101) target region were used for further characterization of the repression characteristics.

The sRNA expression was controlled by the MBA inducible XylS-WT/Pm promoter system. By targeting the constitutively expressed mKate2, repression strength was calculated with decrease in fluorescence intensity (figure 16). Both sRNA constructs showed an overall continuous repression strength over time after induction. (figure 16, A, B) with the highest repression after 20 h of 0.65 +/- 0.033 and 0.61 +/- 0.034 for SgrS and MicC, respectively.
The inducer concentration dependent repression strength was calculated at the time points 10 h and 15 h (figure 16), which showed a linear increase in repression strength with a saturation above 100 mM MBA concentration (figure 16, C, D).

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6. Future perspectives

The composite part makes important contributions for the iGEM registry in form of two novel transcription factors sensing PET and PE, as well as newly characterized sRNA's with different repression strength for use in different systems. Next to our three main contributions, we also introduced a bi-directional terminator (LUZ7 T50, BBa_K4757058), which is capable of efficiently terminating translation from both directions, and two existing ribosomal binding sites. These RBSs were compared to a synthetic designed RBS (BBa_J61100, BBa_J61101, BBa_K4757003). Conducting our experiments in Pseudomonas fluorescens further allowed us to establish a novel chassis organism, which has intriguing bioremediation capabilities.

We think our operon as a composite part has a valuable place for future bacteria-based plastic degradation, as well as enabling future teams to use the basic parts for plastic degradation or P. fluorescens related problem solving.

We think our operon as a composite part has a valuable place for future bacteria-based plastic degradation, as well as enabling future teams to use the basic parts for plastic degradation or P. fluorescens related problem solving.

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